Solid State Behavior of Linear Polyesters and Polyamides |
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Page 164
... hysteresis loop fFal represents the amount of energy dissipated during one cycle . The heat generation rate Q per unit mass is then Q = - 11 f F de m where F is force , l is length , and m is mass of the specimen . In view of the ...
... hysteresis loop fFal represents the amount of energy dissipated during one cycle . The heat generation rate Q per unit mass is then Q = - 11 f F de m where F is force , l is length , and m is mass of the specimen . In view of the ...
Page 237
... were conduced with microtomed rib- bons of 0.1 mm thickness , hysteresis effects were observed , as shown in Fig- ure 18 for sample B. Most of the deformation was Structure Development in Polyesters 237 Deformation behavior.
... were conduced with microtomed rib- bons of 0.1 mm thickness , hysteresis effects were observed , as shown in Fig- ure 18 for sample B. Most of the deformation was Structure Development in Polyesters 237 Deformation behavior.
Page 314
... hysteretic heating is beneficial for FCP resistance , while a decrease in the elastic modulus generally deteriorates it . In case of composites , it was demonstrated that an increase in any factor of the microstructure enhances the ...
... hysteretic heating is beneficial for FCP resistance , while a decrease in the elastic modulus generally deteriorates it . In case of composites , it was demonstrated that an increase in any factor of the microstructure enhances the ...
Contents
SOLID STATE REACTIONS IN LINEAR | 1 |
CHEMICAL HEALING | 43 |
PRACTICAL ASPECTS OF ADDITIONAL SOLID STATE | 59 |
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acid additional solid amorphous annealing Appl aspect ratio behavior birefringence block temperature chain Chem composites copolyester copolymer courtesy crystallinity crystallization curves decreases deformation degree of crystallinity density diameter diffusion domains Dröscher effect Equation exchange reactions extrusion temperature Fakirov fiber axis fibers drawn filament fracture mechanics fracture toughness function heat of fusion heated element higher increasing initial kg/cm² kinetics linear polycondensates load macromolecules Makromol material matrix maximum measurements mechanical melting point microfibrils microstructure mm/min modulus molded molecules morphology nominal draw ratio noncrystalline nylon 6 fibers nylon 66 orientation parameters peak PET fibers phase Phys polyamides polyesters Polymer Sci polymerization properties Reprinted from Ref samples SAXS Schultz semicrystalline shown in Figure solid state polycondensation solid state post-polycondensation solid state reactions Solid-state extrusion specimen spherulite strength stress structure Table tensile terephthalate thermoplastics toughened transesterification transreactions values x-ray yield Zachmann